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|
(************************************************************************)
(* v * The Coq Proof Assistant / The Coq Development Team *)
(* <O___,, * INRIA - CNRS - LIX - LRI - PPS - Copyright 1999-2015 *)
(* \VV/ **************************************************************)
(* // * This file is distributed under the terms of the *)
(* * GNU Lesser General Public License Version 2.1 *)
(************************************************************************)
open Pp
open Util
type argument_type =
(* Basic types *)
| IntOrVarArgType
| IdentArgType
| VarArgType
(* Specific types *)
| GenArgType
| ConstrArgType
| ConstrMayEvalArgType
| QuantHypArgType
| OpenConstrArgType
| ConstrWithBindingsArgType
| BindingsArgType
| RedExprArgType
| ListArgType of argument_type
| OptArgType of argument_type
| PairArgType of argument_type * argument_type
| ExtraArgType of string
let rec argument_type_eq arg1 arg2 = match arg1, arg2 with
| IntOrVarArgType, IntOrVarArgType -> true
| IdentArgType, IdentArgType -> true
| VarArgType, VarArgType -> true
| GenArgType, GenArgType -> true
| ConstrArgType, ConstrArgType -> true
| ConstrMayEvalArgType, ConstrMayEvalArgType -> true
| QuantHypArgType, QuantHypArgType -> true
| OpenConstrArgType, OpenConstrArgType -> true
| ConstrWithBindingsArgType, ConstrWithBindingsArgType -> true
| BindingsArgType, BindingsArgType -> true
| RedExprArgType, RedExprArgType -> true
| ListArgType arg1, ListArgType arg2 -> argument_type_eq arg1 arg2
| OptArgType arg1, OptArgType arg2 -> argument_type_eq arg1 arg2
| PairArgType (arg1l, arg1r), PairArgType (arg2l, arg2r) ->
argument_type_eq arg1l arg2l && argument_type_eq arg1r arg2r
| ExtraArgType s1, ExtraArgType s2 -> CString.equal s1 s2
| _ -> false
let rec pr_argument_type = function
| IntOrVarArgType -> str "int_or_var"
| IdentArgType -> str "ident"
| VarArgType -> str "var"
| GenArgType -> str "genarg"
| ConstrArgType -> str "constr"
| ConstrMayEvalArgType -> str "constr_may_eval"
| QuantHypArgType -> str "qhyp"
| OpenConstrArgType -> str "open_constr"
| ConstrWithBindingsArgType -> str "constr_with_bindings"
| BindingsArgType -> str "bindings"
| RedExprArgType -> str "redexp"
| ListArgType t -> pr_argument_type t ++ spc () ++ str "list"
| OptArgType t -> pr_argument_type t ++ spc () ++ str "opt"
| PairArgType (t1, t2) ->
str "("++ pr_argument_type t1 ++ spc () ++
str "*" ++ spc () ++ pr_argument_type t2 ++ str ")"
| ExtraArgType s -> str s
type ('raw, 'glob, 'top) genarg_type = argument_type
type 'a uniform_genarg_type = ('a, 'a, 'a) genarg_type
(** Alias for concision *)
(* Dynamics but tagged by a type expression *)
type rlevel
type glevel
type tlevel
type 'a generic_argument = argument_type * Obj.t
type raw_generic_argument = rlevel generic_argument
type glob_generic_argument = glevel generic_argument
type typed_generic_argument = tlevel generic_argument
let rawwit t = t
let glbwit t = t
let topwit t = t
let wit_list t = ListArgType t
let wit_opt t = OptArgType t
let wit_pair t1 t2 = PairArgType (t1,t2)
let in_gen t o = (t,Obj.repr o)
let out_gen t (t',o) = if argument_type_eq t t' then Obj.magic o else failwith "out_gen"
let genarg_tag (s,_) = s
let has_type (t, v) u = argument_type_eq t u
let unquote x = x
type ('a,'b) abstract_argument_type = argument_type
type 'a raw_abstract_argument_type = ('a,rlevel) abstract_argument_type
type 'a glob_abstract_argument_type = ('a,glevel) abstract_argument_type
type 'a typed_abstract_argument_type = ('a,tlevel) abstract_argument_type
type ('a, 'b, 'c, 'l) cast = Obj.t
let raw = Obj.obj
let glb = Obj.obj
let top = Obj.obj
type ('r, 'l) unpacker =
{ unpacker : 'a 'b 'c. ('a, 'b, 'c) genarg_type -> ('a, 'b, 'c, 'l) cast -> 'r }
let unpack pack (t, obj) = pack.unpacker t (Obj.obj obj)
(** Type transformers *)
type ('r, 'l) list_unpacker =
{ list_unpacker : 'a 'b 'c. ('a, 'b, 'c) genarg_type ->
('a list, 'b list, 'c list, 'l) cast -> 'r }
let list_unpack pack (t, obj) = match t with
| ListArgType t -> pack.list_unpacker t (Obj.obj obj)
| _ -> failwith "out_gen"
type ('r, 'l) opt_unpacker =
{ opt_unpacker : 'a 'b 'c. ('a, 'b, 'c) genarg_type ->
('a option, 'b option, 'c option, 'l) cast -> 'r }
let opt_unpack pack (t, obj) = match t with
| OptArgType t -> pack.opt_unpacker t (Obj.obj obj)
| _ -> failwith "out_gen"
type ('r, 'l) pair_unpacker =
{ pair_unpacker : 'a1 'a2 'b1 'b2 'c1 'c2.
('a1, 'b1, 'c1) genarg_type -> ('a2, 'b2, 'c2) genarg_type ->
(('a1 * 'a2), ('b1 * 'b2), ('c1 * 'c2), 'l) cast -> 'r }
let pair_unpack pack (t, obj) = match t with
| PairArgType (t1, t2) -> pack.pair_unpacker t1 t2 (Obj.obj obj)
| _ -> failwith "out_gen"
(** Creating args *)
let (arg0_map : Obj.t option String.Map.t ref) = ref String.Map.empty
let create_arg opt name =
if String.Map.mem name !arg0_map then
Errors.anomaly (str "generic argument already declared: " ++ str name)
else
let () = arg0_map := String.Map.add name (Obj.magic opt) !arg0_map in
ExtraArgType name
let make0 = create_arg
let default_empty_value t =
let rec aux = function
| ListArgType _ -> Some (Obj.repr [])
| OptArgType _ -> Some (Obj.repr None)
| PairArgType(t1, t2) ->
(match aux t1, aux t2 with
| Some v1, Some v2 -> Some (Obj.repr (v1, v2))
| _ -> None)
| ExtraArgType s ->
String.Map.find s !arg0_map
| _ -> None in
match aux t with
| Some v -> Some (Obj.obj v)
| None -> None
(** Registering genarg-manipulating functions *)
module type GenObj =
sig
type ('raw, 'glb, 'top) obj
val name : string
val default : ('raw, 'glb, 'top) genarg_type -> ('raw, 'glb, 'top) obj option
end
module Register (M : GenObj) =
struct
let arg0_map =
ref (String.Map.empty : (Obj.t, Obj.t, Obj.t) M.obj String.Map.t)
let register0 arg f = match arg with
| ExtraArgType s ->
if String.Map.mem s !arg0_map then
let msg = str M.name ++ str " function already registered: " ++ str s in
Errors.anomaly msg
else
arg0_map := String.Map.add s (Obj.magic f) !arg0_map
| _ -> assert false
let get_obj0 name =
try String.Map.find name !arg0_map
with Not_found ->
match M.default (ExtraArgType name) with
| None ->
Errors.anomaly (str M.name ++ str " function not found: " ++ str name)
| Some obj -> obj
(** For now, the following function is quite dummy and should only be applied
to an extra argument type, otherwise, it will badly fail. *)
let obj t = match t with
| ExtraArgType s -> Obj.magic (get_obj0 s)
| _ -> assert false
end
(** Hackish part *)
let arg0_names = ref (String.Map.empty : string String.Map.t)
(** We use this table to associate a name to a given witness, to use it with
the extension mechanism. This is REALLY ad-hoc, but I do not know how to
do so nicely either. *)
let register_name0 t name = match t with
| ExtraArgType s ->
let () = assert (not (String.Map.mem s !arg0_names)) in
arg0_names := String.Map.add s name !arg0_names
| _ -> failwith "register_name0"
let get_name0 name =
String.Map.find name !arg0_names
module Unsafe =
struct
let inj tpe x = (tpe, x)
let prj (_, x) = x
end
|